Flow Sensor

ABSTRACT

Flow sensors are provided that can provide both leak detection and flow monitoring. The flow monitoring enables a determination whether there are blockages or leaks in a fluid system during normal operation of the system. The leak detection enables detection of leaks when the system is shut off. The flow sensors can use a frusto-conical flow guide to provide a more compact flow sensor. The flow sensor components can be designed to retrofit existing filter assemblies.

FIELD

The present invention relates to monitoring fluid flow and, more particularly, to flow devices and methods for monitoring fluid flow and leaks.

BACKGROUND

Fluid systems, such as irrigation systems, are controlled by components, such as valves, upstream in the system. These control components are known to leak from time-to-time. The leaks can be caused by debris being caught between the valve member and the valve seat or the results of normal wear and tear on the valve. Also, in many fluid systems, there are fluid distribution devices downstream from the control components. For example, irrigation systems include water emitting devices downstream of the control components. These water emitting devices also can become defective from normal wear and tear or can be damaged from normal lawn care or by vandalism. As a result, excessive water is distributed from the system. Also, the piping or conduit in such system can be damaged. For instance, one could unintentionally spike buried irrigation conduits with a shovel or other tool or machine during lawn care. Further, fluid systems can develop blockage in the lines and the components which will cause an undesired amount of fluid to be delivered through system. With an irrigation system, this could result in insufficient water being delivered to the vegetation. Overall, the damage or interference with proper flow in a fluid system can result in damage and additional cost.

It is desired to have a flow sensor and method that easily and cost effectively monitors for leaks and measures flow in the fluid system.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a flow sensor;

FIG. 2 is a central cross-sectional view of the flow sensor of FIG. 1;

FIG. 3 is an exploded view of the flow sensor of FIG. 1;

FIG. 4 is a perspective view of another flow sensor;

FIG. 5 is a central cross-section view of the flow sensor of FIG. 4;

FIG. 6 is an exploded view of the flow sensor of FIG. 4;

FIG. 7 is a perspective view of another flow sensor;

FIG. 8 is a central cross-section view of the flow sensor of FIG. 7;

FIG. 9 is an exploded view of the flow sensor of FIG. 7;

FIG. 10 is a bottom perspective view of a top cover of the flow sensor of FIG. 7;

FIG. 11 is a top perspective view of an intermediate cover of the flow sensor of FIG. 7;

FIG. 12 is a top perspective view of a base of the flow sensor of FIG. 7;

FIG. 13 is a bottom perspective view of a funnel of the flow sensor of FIG. 7;

FIG. 14 is a top perspective view of a piston, top cap, and rotating strip of the flow sensor of FIG. 7;

FIG. 15 is a perspective view of the top cap and piston of the flow sensor of FIG. 7;

FIG. 16 is a bottom perspective view of a shaft cap of the flow sensor of FIG. 7;

FIG. 17 is a central cross-section view of another flow sensor;

FIG. 18 is a perspective view of a filter of the flow sensor of FIG. 17;

FIG. 19 is a perspective view of an alternate flow sensor;

FIG. 20 is an exploded view of an inlet, an outlet, and a flow sensor body of the flow sensor of FIG. 19;

FIG. 21 is a central cross-sectional view of the flow sensor of FIG. 19;

FIG. 22 is an exploded view of a portion of the flow sensor of FIG. 19;

FIG. 23 is a partial cross-sectional view of the body and a flow guide of the flow sensor of FIG. 19;

FIG. 24 is a bottom perspective view of the flow guide of the flow sensor of FIG. 19;

FIG. 25 is a top perspective view of the body of the flow sensor of FIG. 19;

FIG. 26 is a top perspective, exploded view of a piston of the flow sensor of FIG. 19;

FIG. 27 is a top perspective view of a twisted shaft of the flow sensor of FIG. 19 and the piston of FIG. 26;

FIG. 28 is a top perspective, cross-sectional view of a washer of the flow sensor of FIG. 19;

FIG. 29 is a central cross-sectional view of an enclosure of the flow sensor of FIG. 19 and the washer of FIG. 28;

FIG. 30 is a bottom plan view of the enclosure of FIG. 29;

FIG. 31 is a bottom perspective view of the enclosure of FIG. 29;

FIG. 32 is a forward of center cross-sectional, perspective view of the enclosure, the twisted shaft, a helical spring, and the piston of the flow sensor of FIG. 19;

FIG. 33 is a side perspective view of a spindle of the flow sensor of FIG. 19;

FIG. 34 is a central cross-sectional view of the spindle of FIG. 33 and a lock clip and a seal of the flow sensor of FIG. 19 associated with the spindle;

FIG. 35 is a perspective view of a dial assembly of the flow sensor of FIG. 19;

FIG. 36 is a top perspective view of a top cover of the flow sensor of FIG. 19;

FIG. 37 is a central cross-sectional view of the flow sensor of FIG. 19 with a cylindrical flow guide;

FIG. 38 is a bottom perspective view of the cylindrical flow guide of FIG. 37;

FIG. 39 is a central cross-sectional view of an alternative flow sensor;

FIG. 40 is an exploded view of a portion of the flow sensor of FIG. 39;

FIG. 41 is a cross-sectional view of a body and a single piece flow guide/filter of the flow sensor of FIG. 39;

FIG. 42 is a bottom perspective view of the single piece flow guide/filter of the flow sensor of FIG. 39;

FIG. 43 is a central cross-sectional view of the single piece flow guide/filter of FIG. 42;

FIG. 44 is a top perspective view of the body of the flow sensor of FIG. 39;

FIG. 45 is a top perspective, central cross-sectional view of a washer of the flow sensor of FIG. 39;

FIG. 46 is a central cross-sectional view of a top cover of the flow sensor of FIG. 39 and the washer of FIG. 45;

FIG. 47 is a bottom perspective view of the top cover of FIG. 46;

FIG. 48 is a bottom plan view of the top cover of FIG. 46;

FIG. 49 is a perspective view of a dial assembly of the flow sensor of FIG. 39;

FIG. 50 is a side perspective view of the top cover, the dial assembly and a flow gauge of the flow sensor of FIG. 39;

FIG. 51 is a top perspective view of the top cover of the flow sensor of FIG. 39;

FIG. 52 is a bottom perspective view of a dial seat of the dial assembly of FIG. 49;

FIG. 53 is a side perspective view of the flow gauge of FIG. 50;

FIG. 54 is an exploded view of an alternative top cover, flow gauge and dial assembly;

FIG. 55 is an exploded view of the flow gauge of FIG. 54;

FIG. 56 is side perspective view of the top cover, flow gauge and dial assembly of FIG. 54;

FIG. 57 is a cross-sectional view of the top cover, flow gauge and dial assembly of FIG. 54; and

FIG. 58 is a bottom plan view of top cover of FIG. 54.

DETAILED DESCRIPTION

Referring to FIGS. 1-3, there is shown a flow sensor 10. The flow sensor 10 can be embedded into a fluid system, such as an irrigation system. The flow sensor 10 includes an inlet 12 portion, a leak detector 14, a flow meter 16 and an outlet portion 18. The leak detector 14 monitors upstream components, such as a valve, for leaks. The flow meter 16 monitors flow to detect whether the flow is above or below a normal amount or range for the system. For example, in an irrigation system, if the flow is above a normal amount or range, this indicates that there is a leak downstream in the system, such as in the conduit and/or watering emission device(s). On the other hand, if the flow is below the predetermined amount, this indicates that there may be a clog in the system, such as in the flow conduit and/or watering emission device(s) or that the valve upstream is not operating properly.

The inlet portion 12 and the outlet portion 18 are configured for attachment of the flow sensor 10 to conduit in the system. As illustrated, the inlet portion 12 includes exterior threading 20, which can be male NPT thread, for being threaded into an interior threaded conduit end. The outlet portion 18 includes internal threading 22, which can be female NPT thread, for cooperating with external threading on a downstream conduit end. Alternatively, the inlet portion and outlet portion could both be male threaded or female threaded. Also, instead of threading, the inlet portion and the outlet portion could have smooth surfaces that are glued to the inner and outer surfaces of the upstream conduit and downstream conduit, respectively. The inlet portion 12 extends from the leak detector 14, and the outlet portion 18 extends from a portion of the flow meter 16.

The leak detector 14 includes a housing 24 disposed between the inlet portion 12 and the flow sensor 16. The housing 24 can be a two piece housing with an upstream portion 24 a and a downstream portion 24 b. Alternatively, the housing could be one piece. The housing 24 includes a lower portion 26 that provides a flow passage 28 to the flow meter 16 and an upper portion 34 that provides a leak indicator system 30.

The leak detector 14 includes a chamber 32 extending upward from the lower portion 26 of the housing 24. The chamber 32 is defined by the upper portion 34 of the housing 24 and includes a transparent upper portion 34 a and an opaque or semi-transparent lower portion 34 b. Alternatively, as explained further below, the upper portion 34 a and the lower portion 34 b both could be opaque or semi-transparent, and a third portion 34 c in between the upper and lower portions 34 a, 34 b could be transparent. The leak detector 14 further includes a flow indicator 36 and a spring 38 disposed on a shaft 40. The shaft 40 includes a head 42 that is used to pin the shaft 40 to an upper end 44 of the upper portion 34 of the housing 24. The spring 38 is disposed between the upper end 44 of the chamber 32 and the flow indicator 36 to bias the flow indicator 36 down into the opaque portion 34 b of the chamber 32.

The chamber 32 is able to receive fluid flow from the passage 28. More specifically, the housing 24 forms an annular chamber 33 and defines a first opening 35 to the annular chamber 33 from the flow passage 28. The first opening 35 is located diametrically opposite from the chamber 32. The annular chamber 33 has a second opening 37 at the annular chamber 33. Fluid flows from the passage 28 through the first opening 35, around the annular chamber 33 (through one or both sides) and, then, through the second opening 37 into the chamber 32 of the leak detector 14. A drain passage 46 is on the downstream side of the chamber 32. The drain passage 46 dumps fluid flowing through the leak detector 14 into the flow meter 16.

In operation, when pressurized flow of fluid to the flow sensor 10 is discontinued, the flow meter 16 closes so that fluid cannot flow further downstream, such as due to gravity. If flow continues on the upstream side, it will flow through the annular chamber 33 and cause the flow indicator 36 to rise upward in the chamber 32 against the bias of the spring 38. The spring force is selected so that the flow indicator 36 can detect very small amounts of flow, such as that from a leaking control valve of an irrigation system. When there is a leak, the flow indicator 36 will rise up on the shaft 40 in the chamber 32 into the transparent portion 34 a of the upper portion 34 or in another form of the embodiment into the transparent portion 34 c. The flow indicator 36 can be of a color, such as red, that is easily seen through the transparent portion 34 a or 34 c of the upper portion 34.

When the system is operating normally, the flow indicator 36 does not indicate a leak situation. In one embodiment, the chamber 32 can be bypassed by the flow through the sensor 10. To do so, the second inlet 32 to the chamber 32 can be oriented to face downstream or the housing 24 can be angled upstream, or both features can be used. This upstream orientation renders it difficult for the downstream moving flow to form an upstream flow to access the chamber 32. Also, the second opening 37 can be made relatively small. In another embodiment, the second inlet 37 could allow flow into the chamber 37, but the housing 24 would have three portions, as mentioned above. The lower and upper opaque or semi-transparent portions 34 a, 34 b and the transparent center portion 34 c between portions 34 a, 34 b. When flow is flowing normally, the flow also would flow through the leak detector 14 moving the flow indicator 36 up to the upper opaque portion 34 a. When the flow is off, the flow indicator 36 moves to the lower opaque portion 34 b. If there is a leak detected, the flow indicator 36 would move to the transparent center portion 34 c.

The flow meter 16 includes a conical housing 48 that enlarges in the downstream direction and can be transparent. The flow meter 16 further includes a piston 50 connected to one end of a shaft 52 and spring 54 disposed about the shaft 52. More specifically, the piston 50 is held at the end of shaft 52 by a shaft head 53 and the spring 54. The piston 50 is disc shaped but can be any other shape that restricts flow. The outlet portion 18 includes a center hub 56 that is supported by one or more radial spikes. In the illustrated embodiment, there are three radial spokes 58 interconnecting the hub 56 and the outlet portion 18. The hub 56 includes a central passage 60 through which the shaft 52 translates as the piston 50 moves back and forth. Alternatively, the shaft 52 could be fixed against movement relative to the passage 60, and the piston 50 could reciprocate along the shaft 52. In this alternate embodiment, the piston 50 would not be fixed to the end of the shaft 52. The spring 54 engages the piston 50 and an enlarged landing 63 on the central hub 56 to bias the piston 50 toward a seat 62 formed about the inner perimeter of the downstream side of the housing 24 of the leak detector 14.

The piston 50, the spring 54 and the conical housing 48 are coordinated to measure flow through the conical housing 48. Since the piston 50 has a constant diameter, the radial distance between a perimeter 51 of the piston 50 and the conical housing 48 increases as the piston 50 translates downstream. This enables the flow meter to have a reduced overall length when compared to a constant diameter housing. More specifically, in general, higher velocities mean a higher force on the piston 50. For an expanding area, such as that provided by the conical housing 48, the velocity will decrease over the length for a given flow rate. So, at higher flow rates, the piston 50 will be located in a section of the conical housing 48 with a larger cross-sectional area, and therefore, have a lower velocity. The advantage is that the flow meter can be shorter for the same flow rate range, and there will be a lower pressure drop.

The foregoing is illustrated by the following examples. In a first example, the conical housing has an inlet diameter of 1.0 in., an outlet diameter of 1.48 in., and an axial length of 1.8 in. The piston has a diameter of 0.97 in., and the spring rate is 0.50 lb/in. In operation, the following table shows the piston position from the inlet and the spring displacement for 5.0 gpm and 20.0 gpm flow rates.

Flow Rate Piston Position From Spring Displacement (gpm) Inlet (in.) (in.) 5.0 0.52 0.52 20.0 1.75 1.75

In a second example for comparison, a straight housing has a diameter of 1.0. The piston has a diameter of 0.97, and a spring rate of 0.50. In operation, the following table shows the spring displacement for 1.0 gpm and 20.0 gpm flow rates.

Flow Rate (gpm) Spring Displacement (in.) 5.0 0.52 20.0 8.33

The comparison of the spring displacements demonstrates that the conical housing can be much shorter than the straight housing. For a flow rate of 20.0 gpm, the conical housing has a spring displacement of 1.75 in. versus 8.33 in. for the straight housing.

When there is no pressurized flow in the system, the piston 50 rests on the seat 52 and prevents flow from draining downstream in the system. The seat 52 or the upstream surface of the piston 50 that engages the seat 52 could include an elastomeric material that enhances the seal between the two. In this position, the drain passage 46 of the flow detector dumps fluid flowing through the leak detector 14 into the flow meter 16 downstream of the piston 50.

When pressurized flow is on, the piston 50 moves downstream a distance dependent on the flow amount. The piston 50 movement can be visualized through the transparent conical housing 48. When the system is operating normally, the piston 50 moves downstream about same amount every time the system is pressurized. There may be slight variations in the distances due to supply pressure fluctuations. This distance or range can be saved using a sliding indicator 64 on the top of the conical housing 48.

More specifically, the top of the conical housing 48 includes a linear track 66 having a predetermined cross-section. The bottom of the sliding indicator 64 includes a complementary slot 68 to receive and translate along the track 66. As illustrated, the track 66 can have a T-shape cross-section, but other cross-sections can be used as well. There is sufficient friction between the linear track 66 and the slot 68 so that the sliding indicator 64 does not inadvertently translate. Also, a set screw (not shown) can be threaded through a hole in the sliding indicator 64 to engage the track 66 to further prevent unintentional movement of the sliding indicator 64 along the track 66. The set screw can include a head configured for use with only a tool, such as an Allen wrench or screwdriver. This will help prevent unintentional movement of the slider because the slider will require a tool to be loosened and normal vibrating will not cause the slider to move inadvertently. The sliding indicator 64 also defines a window 70 that one can use to center the sliding indicator 64 over the piston 50 to record the location of the piston 50 when the fluid system is operating normally. This positioning may be checked over a few iterations of turning on and off the system over a couple of days to account for fluctuations in supply pressure. Further, the track 66 can include a scale 65 indicating a particular number of gallons per minute or hour flowing through the flow sensor 10. Due to the conical design of the housing 48, the scale may not be linear in that the tick mark spacing may vary and become closer towards one end.

The sliding indicator 64 also may include coloring to aid in determining the operation of the fluid system. For example, sides 72 of the window 70 may be colored green to indicate proper operation, and ends 74 of the window 70 may be colored red to indicate improper operation. When the piston 50 is positioned in the window 70 along the green sides 70 of the window, the system is operating normally. On the other hand, when the piston 50 is downstream of the red on the downstream end 74 of the window 70, this would indicate that there is too much flow through the system. Accordingly, the system should be checked for leaks. In an irrigation system, for instance, the excess flow could be a nozzle missing from a sprinkler device or breaks in the conduit. Similarly, when the piston 50 is upstream of the red on the upstream end 74 of the window 70, this would indicate that there is insufficient flow through the system. The system should be checked to make sure that there are no clogs upstream and downstream in the system. In an irrigation system, one should check to make sure the upstream valve is operating properly to provide proper flow and that there are no downstream irrigation devices that are failing or working improperly, such as being clogged.

Referring to FIGS. 4-6, there is shown another flow sensor 110. The flow sensor 110 also can be embedded into a fluid system, such as an irrigation system. The flow sensor 110 includes an inlet 112 portion, a leak detector 114, a flow meter 116 and an outlet portion 118. The leak detector 114 monitors upstream components, such as a valve, for leaks. The flow meter 116 monitors flow to detect whether the flow is above or below a normal amount or range for the system. For example, in an irrigation system, if the flow is above a normal amount or range, this indicates that there is a leak downstream in the system, such as in the conduit and/or watering emission device(s). On the other hand, if the flow is below the predetermined amount, this indicates that there may be a clog in the system, such as in the flow conduit and/or watering emission device(s) or that the valve upstream is not operating properly.

The inlet portion 112 and the outlet portion 118 are configured for attachment of the flow sensor 10 to conduit in the system. As illustrated, the inlet portion 112 includes exterior threading 120, which can be male NPT thread, for being threaded into an interior threaded conduit end. The outlet portion 118 includes internal threading 122, which can be female NPT thread, for cooperating with external threading on a downstream conduit end. Alternatively, the inlet portion and outlet portion could both be male threaded or female threaded. Also, instead of threading, the inlet portion and the outlet portion could have smooth surfaces that are glued to the inner and outer surfaces of the upstream conduit and downstream conduit, respectively. The inlet portion 112 extends from the leak detector 114, and the outlet portion 118 extends from a portion of the flow meter 116.

The leak detector 114 includes a housing 124 disposed between the inlet portion 112 and the flow meter 116. The housing 124 can be a two piece housing with an upstream portion 124 a and a downstream portion 124 b. The leak detector also can be a single piece. The housing 124 includes a lower portion 126 that provides a flow passage 128 to the flow meter 116 and an upper portion 134 that provides a leak indicator system 130.

The leak detector 114 includes a chamber 132 extending upward from the lower portion 126 of the housing 124. The chamber 132 is defined by the upper portion 134 of the housing 124 and includes a transparent upper portion 134 a and an opaque or semi-transparent lower portion 134 b. Alternatively, as with the previous embodiment, the upper portion 134 a and the lower portion 134 b both could be opaque or semi-transparent, and a third portion 134 c in between the upper and lower portions 134 a, 134 b could be transparent. The leak detector 114 further includes a flow indicator 136 and a spring 138 disposed on a shaft 140. The shaft 140 includes a head 142 that is used to pin the shaft 140 to an upper end 144 of the upper portion 134 of the housing 124. The spring 138 is disposed between the upper end 144 of the chamber 132 and the flow indicator 136 to bias the flow indicator 136 down into the opaque portion 134 b of the chamber 132.

The chamber 132 is able to receive fluid flow from the passage 128. More specifically, the housing 124 forms an annular chamber 133 and defines a first opening 135 to the annular chamber 133 from the flow passage 128. The first opening 135 is located diametrically opposite from the chamber 132. The annular chamber 133 has a second opening 137 at the annular chamber 133. Fluid flows from the passage 128 through the first opening 135, around the annular chamber 133 (through one or both sides) and, then, through the second opening 137 into the chamber 132 of the leak detector 114. A drain passage 146 is on the downstream side of the chamber 132. The drain passage 146 dumps fluid flowing through the leak detector 114 into the flow meter 116.

In operation, when pressurized flow of fluid to the flow sensor 110 is discontinued, the flow meter 116 closes so that fluid cannot flow further downstream, such as due to gravity. If flow continues on the upstream side, it will flow through the annular chamber 133 and cause the flow indicator 136 to rise upward in the chamber 132 against the bias of the spring 138. The spring force is selected so that the flow indicator 136 can detect very small amounts of flow, such as that from a leaking control valve of an irrigation system. When there is a leak, the flow indicator 136 will rise up on the shaft 140 in the chamber 132 into the transparent portion 134 a of the upper portion 134 or in another form of the embodiment into the transparent portion 134 c. The flow indicator 136 can be of a color, such as red, that is easily seen through the transparent portion 134 a or 134 c of the upper portion 134, depending on the design.

When the system is operating normally, the flow indicator 136 does not indicate a leak situation. In one embodiment, the chamber 132 can be bypassed by the flow through the sensor 110. To do so, the second inlet 132 to the chamber 132 can be oriented to face downstream or the housing 124 can be angled upstream, or both features can be used. This upstream orientation renders it difficult for the downstream moving flow to form an upstream flow to access the chamber 132. Also, the second opening 137 can be made relatively small. In another embodiment, the second inlet 137 could allow flow into the chamber 137, but the housing 124 would have three portions, as mentioned above. The lower and upper opaque or semi-transparent portions 134 a, 134 b and the transparent center portion 134 c between portions 134 a, 134 b. When flow is flowing normally, the flow also would flow through the leak detector 114 moving the flow indicator 136 up to the upper opaque portion 134 a. When the flow is off, the flow indicator 136 moves to the lower opaque portion 134 b. If there is a leak detected, the flow indicator 136 would move to the transparent center portion 134 c.

The flow meter 116 includes a conical housing 148 that enlarges in the downstream direction and can be transparent. An upper housing 150 extends from the conical housing 148 and is transparent. The upper housing 150 includes a pair of depending hinge points 152 used with a hinge pin 154 to attach a valve door 156, a torsional spring 158 and a flow indicator 160 to the upper housing 150. The valve door 156 pivots includes a pair of arms 157 that define hinge holes at their ends, and the valve door 156 pivots about the hinge pin 154 depending on the amount of flow through the conical housing 148. The valve door 156 is generally disc shaped. The spring 158 includes a center portion that forms a loop 162 that wraps around a post 164 projecting from a downstream side 166 of the valve door 156. The spring 158 has a coil 168 on each side of the loop 162 that each terminates with a tail portion 170 that engages an upstream inner surface 172 of the upper housing 150. The hinge pin 154 extends through the coils 168. The spring 158 biases the valve door 156 in the upstream direction toward a seat 161 formed about the inner perimeter of the downstream side of the housing 24 of the leak detector 14. The valve door 156 moves the flow indicator 160 depending on the flow through conical housing 148.

More specifically, the flow indicator 160 has a first linear leg 162 with one end caring an adjustment pin 176 that engages the downstream side 166 of the valve door 156 below the post 164 and the other end forming a pivot hole 178 for the hinge pin 154. The pivot hole 178 receives the hinge pin 154 between the coils 168 of the spring 158. The adjustment pin 176 could be adjustable (e.g., a set screw) in the first linear leg 162 to calibrate the flow indicator 160. The flow indicator 160 has a second linear leg 180 that extends downstream from the pivot hole 178 to an arcuate leg 182 that curves upstream. The arcuate leg 182 moves in the upper housing 150 to provide a visual indication of the flow.

The valve door 156, the spring 158 and the conical housing 148 are coordinated to measure flow through the conical housing 148. Since the valve door 156 is circular with a constant diameter, the radial distance between a perimeter 184 of the piston valve door 156 and the conical housing 148 increases as the valve door 156 pivots downstream. Similar to the piston embodiment above, as the door 156 pivots downstream, the area increases, and the velocity decreases. Also, as the door 156 pivots downstream, there will be less drag on the door so its movement increments will become smaller as the flow increases. This enables the flow meter to have a reduced overall length when compared to a constant diameter housing. When there is no pressurized flow in the system, the valve door 156 rests on the seat 161 and prevents flow from draining downstream in the system. The seat 161 or an upstream surface 186 of the valve door 156 that engages the seat 161 could include an elastomeric material that enhances the seal between the two. In this position, the drain passage 146 of the leak detector dumps fluid flowing through the leak detector into the flow meter 116 downstream of the valve door 156.

When pressurized flow is on, the valve door 156 pivots downstream an amount dependent on the flow amount. The valve door 156 movement can be visualized by reference to the corresponding movement of the arcuate leg 182 of the flow indicator 160 through the transparent upper housing 150. When the system is operating normally, the valve door 156 pivots downstream about same amount every time the system is pressurized. There may be slight variations in the amount due to supply pressure fluctuations. This pivot amount can be saved using a sliding indicator on the top of the upper housing 150. While this sliding indicator is not shown, it can be the same design as that for the flow sensor 10. In sum, the top of the upper housing can include a track with a particular cross-section, such as a T shape cross-section. The track would trace the arc across the top of the upper housing 150. Other cross-sections can be used as well. The bottom of the sliding indicator includes a complementary slot to the track so that it can receive and translate along the track. A set screw with a tool configured head can be used to lock the sliding indicator in place. The sliding indicator also defines a window that one can use to center the sliding indicator over a terminal end 188 of the arcuate leg 182 of the flow indicator 136 when the fluid system is operating normally. Further, the track can include a scale indicating a particular number of gallons per minute or hour flowing through the flow sensor 110. Due to the conical design of the housing 148, the scale may not be linear in that the tick mark spacing may vary and become closer towards one end. Other designs could be employed as well. For example, the pivoting of the door could be translated into a linear movement or movement of a dial indicator.

As with flow sensor 10, the sliding indicator also may include coloring to aid in determining the operation of the fluid system. For example, sides of the window may be colored green to indicate proper operation, and ends of the window may be colored red to indicate improper operation. When the terminal end 188 of the flow indicator 160 is positioned in the window along the green sides of the window, the system is operating normally. On the other hand, when the terminal end 188 of the flow indicator 160 is downstream of the red on the downstream end of the window, this would indicate that there is too much flow through the system. Accordingly, the system should be checked for leaks. In an irrigation system, for instance, the excess flow could be a nozzle missing from a sprinkler device or breaks in the conduit. Similarly, when the terminal end 188 of the flow indicator 160 is upstream of the red on the upstream end of the window, this would indicate that there is insufficient flow through the system. The system should be checked to make sure that there are no clogs upstream and downstream in the system. In an irrigation system, one should check to make sure the upstream valve is operating properly to provide proper flow and that there are no downstream irrigation devices that are failing or working improperly, such as being clogged.

With reference to FIGS. 7-18, there is shown a flow sensor 210. The flow sensor 210 can be embedded into a fluid system, such as an irrigation system. The flow sensor 210 includes an inlet 212, a flow meter 214 and an outlet 216. The flow meter 214 monitors flow to detect whether the flow is above or below a normal amount or range for a current state of the system. For example, in an irrigation system, if the flow is above a normal amount or range, this indicates that there is a leak downstream in the system, such as in the conduit and/or watering emission device(s). On the other hand, if the flow is below the predetermined amount, this indicates that there may be a clog in the system, such as in the flow conduit and/or watering emission device(s) or that the valve upstream is not operating properly.

The inlet 212 and the outlet 216 are configured for attachment of the flow sensor 210 to conduit in the system. As illustrated, the inlet 212 includes exterior threading 218, which can be male NPT threading, for being threaded into an interior threaded conduit end. The inlet 212 also includes a flange 220 for attachment to a base 222 of the flow meter 214. The base 222 includes a corresponding flange 224. The flanges 222, 224 include holes 226 that align and are used to secure the flanges 222, 224 using bolts 228, nuts 230 and washers 232. The washers could be lock washers. The flange 220 includes a recess 231 for holding an o-ring 233 to further seal the interface between the flanges 220, 224.

The outlet 216 includes internal threading 234, which can be female NPT threading, for cooperating with external threading on a downstream conduit end. The outlet 216 also includes a flange 236 for attachment to the base 222 of the flow meter 214. The base 222 includes a corresponding flange 238. The flanges 234, 236 include holes 240 that align and are used to secure the flanges 234, 236 using bolts 228, nuts 230 and washers 232. The flange 238 includes a recess 239 for holding an o-ring 241 to further seal the interface between the flanges 236, 238.

The inlet 212 and the outlet 216 each include an annular flange 251, 253 that draws the inlet 212 and the outlet 216 into a sealing engagement with an o-ring 255 disposed in an annular recess 257 and each end of the body 222 facing the inlet 212 and the outlet 216. This quick connect alternative enables the inlet and outlet to be interchangeable to accommodate different connections and pipe sizes. For example, the inlet and outlet could both be male threaded or female threaded. Also, instead of threading, the inlet and the outlet could have smooth surfaces that are glued to the inner and outer surfaces of the upstream conduit and downstream conduit, respectively.

Alternatively, in place of flanges 222, 224, the base 222 could include threaded inlets and outlets for receiving threaded collars as described later in connection with the embodiment of FIGS. 19-36.

The flow meter 214 includes the base 222, an intermediate cover 242 and a top cover 244. The top cover 244 includes a flange 246 for attachment to a flange 248 of the intermediate cover 242. The flanges 246, 248 include holes 250 that align and are used to secure the flanges 246, 248 using bolts 228, nuts 230 and washers 232. The flange 246 includes a recess 247 for holding an o-ring 249 to further seal the interface between the flanges 246, 248.

The intermediate cover 242 attaches to the base 222. The intermediate cover 242 includes radial tabs 252 that each define a hole 254 that aligns with a corresponding hole 256 defined by each bore portion 258 of the base 222. A threaded screw 260 extends through each of the holes 254 of the radial tabs 252 and threads into the hole 256 of each of the bore portions 258 of the base 222. Alternatively, the base 222 and the intermediate cover 242 could be a single piece.

The base 222 defines an inlet passage 262 and an outlet passage 264. The inlet passage 262 is defined in part by an upward directed tubular portion 266 at the center of the base 222. The outlet passage 262 extends around the tubular portion 266 and over a portion of the inlet passage 262 upstream of the tubular portion 266. The base 222 also defines an annular recess 268 adjacent and radially inside of the bore portions 258. The annular recess 268 holds an o-ring 270 that seals against the intermediate cover 242.

The intermediate cover 242 has an inward tapering configuration towards the base 222. The intermediate cover forms a lower chamber 272 and in combination with the top cover 244 defines an upper chamber 274. The lower chamber 272 houses a flow guide 276. The flow guide 276 includes a tubular portion 278 and a frusto-conical portion 280. The flow guide tubular portion 278 extends into the tubular portion 266 of the inlet passage 262. The flow guide tubular portion 278 includes an annular recess 282 about its exterior surface that receives an annular rib 284 projecting from an interior surface of the inlet passage tubular portion 266. This secures flow guide 276 at the base 222. An o-ring 286 is disposed between the exterior surface of the flow guide tubular portion 278 and the interior surface of the inlet passage tubular portion 266 to provide a seal between the two components. The o-ring 286 is held in an annular recess 288 formed in the outer surface of the flow guide 276. The flow guide 276 defines an axially extending slot 290 at its tubular portion 278. The slot 290 receives an axially extending rib 292 projecting from the inlet passage tubular portion 266 of the base 222. The slot 290 and rib 292 align the flow guide 276 for proper orientation during assembly of the flow guide 276 to the base 222.

The frusto-conical portion 280 of the flow guide 276 allows fluid to flow outward as it moves to the top of the upper chamber 274. The frusto-conical portion 280 may terminate with an upper edge 306 that is curled outward and downward to assist with a smooth transition for the flow from the flow guide 276 down toward the outlet passage. For further assistance in redirecting the flow fluid, the upper chamber 274 includes an arcuate, annular portion 294. The spacing between the outward flare and curled upper edge of the frusto-conical portion 280, on the one hand, and the smooth curvature of the arcuate, annular portion 294 of the upper chamber 274, on the other hand, can be optimized so that pressure drop is reduced. For example, it has been found that reducing the spacing can minimize the pressure drop.

A piston 296 operates in the both the lower and upper chambers 272, 274 of the intermediate cover 242. The piston 296 includes a shaft 298 and an enlarged head 300. The enlarged head 300 operates in the flow guide 276 and fits into the flow guide tubular portion 278 with sufficient clearance so that fluid can flow around the enlarged head 300 to be more sensitive to low flow rates so that they can be measured when the enlarged head 300 is in the flow guide tubular portion 278. The enlarged head 300 includes small radial projections 302 that engage the inner surface of the flow guide tubular portion 278 to center the enlarged head 300 in the flow guide tubular portion 278 and to reduce friction between the enlarged head 300 and the inner surface of the flow guide tubular portion 278 when the piston 296 moves. Also, when the enlarged head 300 is located in the flow guide tubular portion 278, it can rest on a series of tapered ribs 304 extending from the inner surface of the flow guide tubular portion 278 when there is no flow. Alternatively, the tapered ribs 304 could be replaced with a continuous, annular projecting sealing seat for the enlarged head to rest on when there is no flow.

The shaft 298 has a hollow interior 308 and extends through an opening 310 at the top of the intermediate cover 242. The intermediate cover 242 includes a tubular portion 312 that extends about the opening 310 and from the opening 310 to the flange 246. The opening 310 is sized to provide enough clearance so the shaft 298 can reciprocate easily through the opening 310. The opening 310 includes a rib 311 extending inward to be received in longitudinal extending slot 313 in an outer surface of the shaft 298 of the piston 296. The rib 311 and the slot 313 prevent the piston 296 from rotating.

While fluid can fill the upper chamber 274, the upper chamber 274 is not in the path of the primary flow through the flow meter 214. This reduces the potential for debris to be carried into the upper chamber 274 and affect the operation of an instrument 314 housed in the upper chamber 214 that indicates the amount of flow passing through the flow meter 214.

Alternatively, as shown in FIG. 17, an o-ring 316 may be incorporated into an interface between the opening 310 and the shaft 298 to seal against fluid entering the upper chamber 274. The intermediate cover 242 may define an annular recess 318 about the opening 310 to hold the o-ring 316. The o-ring could be the Turcon® Double Delta® and/or made of the material Zrucon® 280. Both are provided by Trelleborg Sealing Solutions of Helsingor, Denmark. The other o-rings discussed herein could be of the same material.

The instrument 314 includes a twisted shaft 320. One end fitted of the twisted shaft 320 has a dial 322, and the other end fits through a slot 324 defined by a cap 326. The cap 326 is attached to the end of the shaft 298 opposite the enlarged head 300. As the shaft 298 moves upward in the upper chamber 274 as flow increases, the twisted shaft 320 moves further into the hollow interior 308 of the shaft 298. The twist in the twisted shaft 320 turns the twisted shaft 320 and dial 322 as the twisted shaft 320 moves into the hollow interior 308 as flow through the flow meter 214 increases. A conical tip 328 extends from a center position of the dial 322 and pivots in a conical dimple 331 on an inside surface 330 of a top wall 332 of the top cover 244 as the dial 322 rotates. The interior of the top cover 244 and the tubular portion 312 of the intermediate cover 242 include a number of longitudinal ribs 333, 335, respectively, extending into the upper chamber 274. The dial 322 translates along the ribs 333, 335. The conical tip 328 and the ribs 333, 335 reduce friction for the operation of the instrument 314 and guide the piston 296 to reduce side loading on the piston 296 when flow through the flow meter 214 is non-symmetrical.

The top wall 332 of the top cover 244 can be transparent to allow visual inspection of the dial 322. The dial 322 and the top wall 332 can include markings that indicate the flow. For example, the dial 322 may include a marking, such as an arrow 334, and the wall 332 may include a scale 336 showing different pressures. A spring 338 in the upper chamber 274 biases the piston 296 downward toward the inlet passage 262. The spring 338 seats in an annular recess 340 at the top of the upper chamber 274 and an annular recess 342 in the shaft cap 326 at the bottom of the upper chamber 274.

The shaft 298 and the shaft cap 326 are splined together such that they do not rotate relative to one another. The shaft 298 includes a longitudinal rib 344 extending into the hollow interior 308. The rib 344 is received in a slot 346 defined by a tubular extension 348 extending from a bottom of the shaft cap 326 that is received in the hollow interior 308 of the shaft 298. The rib 344 and slot 346 spline the shaft 298 and the shaft cap 326 together. The tubular extension 348 can have a stepped configuration where the portion adjacent the bottom of the shaft cap 326 is larger in diameter and forms a friction fit with an inner surface of the shaft 298. In addition to a friction fit between the tubular extension 348 of the shaft cap 326 and the shaft 298, the shaft cap 326 and the shaft 298 also could be glued or welded together. The shaft cap 326 defines a number of holes 350 to allow water and air to pass through the shaft cap 326 as it reciprocates in the upper chamber 274. The holes 350 prevent pressure buildup on the shaft cap 326 that would otherwise affect movement of the piston 296 and the corresponding fluid measurement.

As shown in FIGS. 17 and 18, a filter 352 also may be included to remove debris from fluid before it passes to the outlet passage 264. The filter 352 can be secured in the lower chamber 272 between an annular landing 354 inward of the recess 268 for the o-ring 270 of the base 222 and the curled upper edge 306 of the flow guide 276. The filter 352 can include a top ring 356, a bottom ring 358 and a series of filter support elements 360 extending between the top ring 356 and the bottom ring 358. A mesh or screen 361 could be fixed to the top ring 356, the bottom ring 358 and the filter support elements 360. For example, the mesh or screen could be over-molded onto the top ring 356, the bottom ring 358 and the filter support elements 360. The bottom ring 358 can include a radial flange 362 that can be received in a recess 364 defined by the intermediate cover 242 at the interface with the base 222 to further secure the filter 352.

In operation, fluid flows into the flow sensor 210 through the inlet passage 262. As the flow increases, the fluid moves the piston upwards in the lower and upper chambers 272, 274. The piston causes the instrument 314 to determine the flow rate through the flow sensor 210. That is, the upward movement of the piston 296 against the spring 338 causes the twisted shaft 320 to turn and twist into the hollow interior 308 of the shaft 298. The twisting of the twisted shaft 320 rotates the dial 322 causing the arrow 334 to rotate about the scale 336 indicating the flow through the flow meter 214 of the flow sensor 210. As the flow meter 214 is measuring the flow, the fluid flows around the enlarged head 300 of the piston 296 and through the flow guide 276. Then, the flow is guided by the accurate, annular portion 294 of the intermediate cover 242 and the curled edge 306 of the flow guide 276 to turn direction back towards the outlet passage 264.

The piston 296, the spring 338 and the frusto-conical portion 280 of the flow guide 276 are coordinated to measure flow through flow meter 214. Since the enlarged head 300 of the piston 296 has a constant diameter, the radial distance between a perimeter of the enlarged head 300 and the frusto-conical portion 280 of the flow guide 276 increases as the piston 296 translates downstream. This enables the flow meter 214 to have a reduced overall length (or height) when compared to a constant diameter flow guide. More specifically, in general, higher velocities mean a higher force on the enlarged head 300 of the piston 296. For an expanding area, such as that provided by the frusto-conical portion 280 of the flow guide 276, the velocity will decrease over the length for a given flow rate. So, at higher flow rates, the enlarged head 300 will be located in a section of the frusto-conical portion 280 with a larger cross-sectional area, and therefore, have a lower velocity. The advantage is that the flow meter can be shorter for the same flow rate range, and there will be a lower pressure drop. When there is no pressurized flow in the system, the enlarged head 300 of the piston 296 rests on the tapered ribs of the flow guide 276.

The foregoing is illustrated by the following examples. In a first example, the frusto-conical portion of the flow guide has an inlet diameter of 1.25 in., an outlet diameter of 1.60 in., and an axial length of 2.45 in. The enlarged head of the piston has a diameter of 1.20 in., and the spring rate is 0.80 lb/in. In operation, the following table shows the enlarged head position from start of the frusto-conical portion and the spring displacement for 5.0 gpm and 25.0 gpm flow rates.

Flow Rate Enlarged Head Position Spring Displacement (gpm) From Start (in.) (in.) 5.0 0.19 0.19 25.0 2.05 2.05

For a second example for comparison, a straight flow guide has a diameter of 1.25 in. The piston has a diameter of 1.20 in., and a spring rate of 0.80 lbs/in. In operation, the following table shows the spring displacement for 5.0 gpm and 25.0 gpm flow rates.

Flow Rate (gpm) Spring Displacement (in.) 5.0 0.19 25.0 4.78

The comparison of the spring displacements demonstrates that the frusto-conical portion can be much shorter than a straight flow guide. For a flow rate of 25.0 gpm, the conical housing has a spring displacement of 2.05 in. versus 4.78 in. for the straight housing.

The springs and shafts of the flow sensors can be made of metal, such as stainless steel. The other components of the flow sensors can be made of plastic, such as acrylonitrile butadiene styrene (ABS), polymethyl methacrylate (PMMA), polypropylene (PP), and polyamides (PA). In addition to bolts and nuts, the housing components and the inlet and outlet components can be glued or welded together.

With reference to FIG. 19, there is shown another flow sensor 410. The flow sensor 410 can be embedded into a fluid system, such as an irrigation system. The flow sensor 410 includes an inlet 412, an outlet 416, a body 415, and a flow meter 414.

As shown in FIG. 20, the inlet 412 and the outlet 416 are configured for attachment of the flow sensor 410 to conduits in an irrigation system. As illustrated, an inlet threaded collar 424 a connects an inlet fitting 422 to the body 415 by threading onto exterior threading 418 a of the body 415. An o-ring 421 a seats in an annular recess 417 in the inlet fitting 422 and engages an inlet face 419 a to further seal the inlet fitting 422 to the inlet face 419 a, and prevent water leakage at the inlet 412. The inlet fitting 422 has exterior threading 420 for being threaded into an interior threaded conduit end.

An outlet threaded collar 424 b connects an outlet fitting 426 to the flow sensor 410 by threading onto exterior threading 418 b of the body 415. An o-ring 421 b seats in an annular recess (not shown) in the outlet fitting 426 and further seals the outlet fitting 426 to an outlet face 419 b of the outlet 416. The outlet fitting 426 has internal threading 427 for cooperating with external threading on a downstream conduit end. This configuration enables quick connection to conduits and may accommodate different connections and conduit sizes.

As shown in FIGS. 20-22, the flow meter 414 includes an upper portion 432 and a base portion 440. The upper portion 432 and the base portion 440 form the body 415. The body 415 may be a single continuous piece, with the inlet 412 and the outlet 416 at opposite sides of the base portion 440. The single piece body 415 requires fewer mechanical parts and is both easier to repair and to manufacture and assemble into the flow sensor 410. A top cover 428 includes radial tabs 430 that each define a hole 436, which aligns with a corresponding hole 438 defined by a bore portion 434 of the upper portion 432. A threaded screw 442 extends through each of the holes 436 of the radial tabs 430 and threads into the hole 438 of each of the bore portions 434 of the upper portion 432.

The base portion 440 defines an inlet passage 444 and an outlet passage 446. The inlet passage 444 is defined in part by an upward directed tubular portion 448 at the center of the base 440. The outlet passage 446 extends around the tubular portion 448 and over a portion of the inlet passage 444 upstream of the tubular portion 448.

The upper portion 432 has an inward tapering configuration towards the base 440. The upper portion 432 forms a lower chamber 450 and, in combination with the top cover 428, defines an upper chamber 452. The lower chamber 450 houses a flow guide 454. The flow guide 454 includes a tubular portion 456 followed by a frusto-conical portion 458.

As shown in FIGS. 23-25, the flow guide tubular portion 456 extends into the inlet passage 444. The flow guide tubular portion 456 includes tapered ridges 460. The tapered ridges 460 have a radially inward angled surface 462 and a ledge 470. The tubular portion 456 has a slightly smaller outer diameter than the inner diameter of the inlet passage 444 so that the tubular portion 456 can slide inside the inlet passage 444, wherein a ledge recess 476 of the tubular portion 456 seats on teeth 466 of the inlet passage 444. An annular bead 478 slides past the teeth 466 and extends into an annular groove 480 at a base of the teeth 446, securing the flow guide 454 to the inlet passage 444.

The frusto-conical portion 458 of the flow guide 454 allows water to flow outward as it moves to the top of the upper chamber 452. The frusto-conical portion 458 may terminate with an upper edge 482 that is curled outward and includes an outer surface that also turns downward to assist with a smooth transition for the flow from the flow guide 454 down toward the outlet passage 446. For further assistance in redirecting the flow, the upper chamber 452 includes an arcuate, annular portion 484 (FIG. 21). The spacing between the outward flare and curled upper edge of the frusto-conical portion 458, on the one hand, and the smooth curvature of the arcuate, annular portion 484 (FIG. 21) of the upper chamber 452, on the other hand, can be optimized so that pressure drop is reduced through the flow sensor 410. For example, it has been found that reducing the spacing can minimize the pressure drop.

With reference to FIGS. 21 and 26, a piston 486 operates in the both the lower and upper chambers 450, 452 of the upper portion 432. The piston 486 includes a shaft 488 with a hollow interior 500, a shaft head 506, and a plunger 499. The plunger 499 includes an enlarged head 490 with a tubular portion 498 molded thereto. The enlarged head 490 operates in the flow guide 454 and fits into the flow guide tubular portion 456 with sufficient clearance so that fluid can flow around the enlarged head 490 to be more sensitive to low flow rates so that they can be measured when the enlarged head 490 is in the flow guide tubular portion 456. The tubular portion 498 has an annular bead 492 that engages fingers 494 of the shaft 488. More specifically, the fingers 494 each have a groove 496 that receives the annular bead 492 of the tubular portion 498 allowing the shaft 488 to securely connect to the tubular portion 498 of the plunger 499.

When there is no flow, the enlarged head 490 seats on the ridge ledges 470 of the tapered ridges 460 within the tubular portion 458 of the flow guide 454. The enlarged head 490 is centered in the flow guide 454 by tapered ribs 472 (FIG. 24). When water is flowing through the flow guide 454, the tapered ribs 472 permit the piston 486 to move up and down linearly with minimal friction between the enlarged head 490 and the tapered ridges 460.

In an alternative example shown in FIGS. 37-38, the flow sensor 410 may be include a cylindrical flow guide 600. In this example, the flow guide 600 has a cylindrical portion 602 that extends from a tubular portion 608 and terminates with an upper edge 606. The tubular portion 608 retains all of the same structure and functionality of the tubular portion 456 of the flow guide 410 as described above. The flow guide 600 has straight (i.e., non-tapered) ribs 604 that center the enlarged head 490 in the flow guide 600 and extend longitudinally along an inside wall of the flow guide 600. The ribs guide the piston 486 while moving up and down linearly with minimum friction between the enlarged head 490 and the tapered ridges 460.

The straight, cylindrical flow guide configuration is commonly more sensitive to flow rates than the frusto-conical flow guide. Thus, in order to cover a range of flow rates as large as the flow guide 454, the flow guide 600 would need to be longer as discussed below. The straight guide can be substituted in each of the designs discussed herein for the frusto-conical flow guide.

As the piston 486 moves upwards, the shaft 488 extends into a tubular portion 510 of an enclosure 502. More specifically, and as shown in FIGS. 26 and 27, the shaft head 506 has a rectangular hole 513 at the center of the shaft head 506. The rectangular hole 513 is of a slightly larger size than the width of the twisted shaft 528. As the rate of water flow increases in the flow meter 414 forcing the piston 486 upwards, the piston 486 will move up the twisted shaft 528, and the twisted shaft 528 will move into the hollow interior 500 of the shaft 488. As a result of this interaction, the twisted shaft 528 will convert the linear motion of the shaft 458 into rotational motion of the twisted shaft 528.

With reference to FIGS. 21 and 32, a base portion 534 of the enclosure 502 seats on a ledge 504 at the top of the upper portion 432. The base portion 534 of the enclosure 502 has a series of recesses 505 to reduce the amount of plastic used in manufacturing. The enclosure 502 is housed in a cavity 538 of the top cover 428. The top cover 428 includes an annular bottom portion 429 that engages a top of the base portion 534 to maintain the base portion 534 in place seated on the ledge 504. A seal 526 provides a sealed engagement between the enclosure 502 and the upper portion 432 of the body 415. The seal 526 seats in an annular recess about the base portion 534.

With reference to FIGS. 21 and 28, the enclosure 502 attaches to a washer 516. The washer 516 is disposed below the shaft head 506 about the shaft 488. The washer 516 has a protrusion 520 that provides slight clearance between the washer 516 and the shaft head 506 for water to flow through holes 507 in the shaft head 506 and into the chamber 452. As shown in FIGS. 29-31, the tubular portion 510 of the enclosure 502 has flexible fingers 514. Each flexible finger 514 can bend radially inward and outward. The flexible fingers 514 slide into holes 522 of the washer 516, and each finger 514 has a lip 515 that clips to the underside of a ledge 523 formed in the each of the holes 522 of the washer 516 and snaps the enclosure 502 securely to the washer 516.

With reference to FIG. 32, the tubular portion 510 houses a helical spring 518 and the twisted shaft 528 in the chamber 452. The shaft head 506 has an annular pocket 509 for the helical spring 518 to seat in. The tubular portion 510 also has ribs 530 (FIG. 31) that run longitudinally therein. The ribs 530 provide enough clearance for the helical spring 518, the shaft 488 and the washer 516 to move up and down linearly. As water flows up the inlet passage 444 and pushes on the piston 486, the piston 486 is biased downward from the helical spring 518. The upward displacement of the piston 486 depends on the rate of flow of the water into the inlet passage 444. A higher flow rate will push the shaft 488 higher into the tubular portion 510 of the enclosure 502 than a lower flow rate. If there is no water flow, the shaft 488 will not extend into the tubular portion 510.

The top of the tubular portion 510 has an annular wall 511. The piston 486 cannot rise vertically beyond the annular wall 511 in the chamber 452. The outer diameter of the annular wall 511 is smaller than the inner diameter of the helical spring 518, and the inner diameter of the tubular portion 510 is larger than the outer diameter of the helical spring 518. Therefore, as the piston 486 drives upward into the chamber 452, the helical spring can coil up and collect around the annular wall 511 and inside the tubular portion 510.

To prevent the piston 486 from rotating within the tubular portion 510 of the enclosure 502, the shaft head 506 has a rib 508 (FIGS. 26 and 27) that slides vertically within a longitudinally running groove 512 (FIG. 30) of the tubular portion 510.

The tubular portion 510 terminates at a top portion 536 (FIG. 21) of the top cover 428. Both the tubular portion 510 and the top portion 536 have a hole (532 of FIG. 30 and 540 of FIG. 22, respectively), that align with one another. With reference to FIGS. 33-35, the holes 532, 540 permit a spindle 542 to connect the twisted shaft 528 to a dial arrow 552 of a dial assembly 544. The spindle 542 has ridges 543 running longitudinally along an upper portion 547 and a lower portion 549. The end of the lower portion 549 fits in the hole 532 of a boss 529 (FIG. 27) of the twisted shaft 528, and the ridges 543 penetrate the surface of the boss 522 forming the hole 532 to prevent rotation of the spindle 542 within the hole 532. The boss 529 also has a series of recesses 531 to reduce the amount of plastic used in manufacturing. A tubular tip 554 extending from a base position 561 of the dial arrow 552 pivots in a dome-shaped recess 556 of the dial cover 550. The end of the upper portion 547 of the spindle 542 has a conical tip 551 that is accommodated by the tubular tip 554. The ridges 543 penetrate into the inner surface of the tubular tip 551 to secure the dial arrow 552 to the spindle 542 and prevent rotation of the spindle 542 within the tubular tip 554 of the dial arrow 552. Therefore, as the spindle 542 rotates due to the rotation of the twisted shaft 528, the dial arrow 552 rotates at the same rate as the spindle 542.

With reference to FIG. 34, a retention clip 553 seats in-between a dome-shaped portion 503 (FIG. 29) of the enclosure 502 and the top portion 536 of the top cover 428. The retention clip 553 is fastened around a groove 545 of an intermediate portion 559 of the spindle 542 to prevent axial movement of the spindle 542. The retention clip 553 has a C-shaped split ring configuration. The dome-shaped portion 503 houses an annular seal 555. The seal 555 has redundant wipers 557 that wrap around and engage the spindle 542 to prevent water from exiting the enclosure 502 through the hole 532 of the tubular portion 510.

Referring to FIG. 35, the dial assembly 544 also includes a dial 546, a helical spring 548, and a transparent dial cover 550. The twisted shaft 528, the spindle 542 and the dial arrow 552 are splined together such that they rotate together. The twist in the twisted shaft 528 turns the twisted shaft 528, the spindle 542 and the dial arrow 552 as the shaft 487 extends higher into the tubular portion 510 of the enclosure 502 as water flow increases through the flow meter 414.

The dial 546 has tabs 558 that seat in complimenting grooves 560 (FIG. 22) of the top cover 428 to prevent the dial 546 from rotating. The helical spring 548 separates the dial 546 and the dial cover 550 to permit the dial arrow 552 to rotate. The dial 546 may be marked with indicia or indicators for the amount of water flow through the flow meter 414. For instance, the dial 546 may have indicia indicating a scale for water flow in gallons per minute and/or liters per minute. As the flow rate increases, the dial arrow 552 will rotate in a clockwise fashion as viewed from above the flow sensor 410.

The dial cover 550 can have color coded sections that designate flow rate ranges. For example, if the flow through a particular system is 10 gpm, a user will use the dial cover 550 to indicate this flow rate of 10 gpm. To do so, a user may remove the screw 564 of the threaded collar 562, and unthread the threaded collar 562 a few turns. This clearance will allow the helical spring 548 to lift the dial cover 550 off of the top cover 428, allowing a user to rotate the dial cover 550. The dial cover 550 has detents 569 at the perimeter that extend from its inward face that seat in incremental pockets 541 (FIG. 36) of the top cover 428. Thus, the user can rotate the dial cover 550 to center a first flow rate indicator section 567 over a marking 570 on the dial 546 indicating 10 gpm. The first flow rate indicator section 567 represents an acceptable range of rate of flow. The first flow rate indicator section 567 may have a semitransparent color (such as semitransparent green). The semitransparent color permits the user to still be able to visually observe the dial arrow 552 and the markings 570 on the dial 546 beneath the dial cover 550. The user may then align the detents 569 with the appropriate pockets 541, thread the threaded collar 562 back on to the top cover 428 to lock the detents 569 in the underlying pockets 541, and further secure the threaded collar 562 with the screw 564.

The dial cover 550 may also have a second, outer flow rate indicator section 568 that is a different semitransparent color (such as semitransparent yellow) and straddles the first, inner flow rate indicator section 567. The outer flow rate indicator section 568 indicates that the flow rate through the flow sensor 410 has either increased or decreased by some percentage beyond the normal gpm range as indicated by the first, inner flow rate indicator section 567.

Finally, as shown in FIG. 22, a threaded collar 562 threads on to the top cover 428 to secure the dial assembly 544 in place. The threaded collar 562 has a hole 566 to accommodate a set screw 564 to pass through and bite into the top cover 428 to prevent unintentional removal of the threaded collar 562 and further secure the threaded collar 562 to the top cover 428. The set screw 564 has a non-traditional tool socket (e.g., a hex tool socket) to aid in prevention of vandalism or unintentional removal. Additionally, the threaded collar 562 could have the transparent dial cover 550 affixed to it.

In operation, fluid flows into the flow sensor 410 through the inlet passage 444. As the flow increases, the fluid moves the piston 486 upwards in the lower and upper chambers 450, 452. The piston 486 causes the dial assembly 544 to determine the flow rate through the flow sensor 410. That is, the upward movement of the piston 486 against the helical spring 518 causes the twisted shaft 528 to turn and twist in the chamber 452. The twisting of the twisted shaft 528 converts linear motion of the piston 486 to rotational motion, and rotates the dial arrow 552 about the dial 546 indicating the flow through the flow meter 414 of the flow sensor 410. As the flow meter 414 is measuring the flow, the fluid flows around the enlarged head 490 of the piston 486 and through the flow guide 454. Then, the flow is guided by the accurate, annular portion 484 of the upper portion 432 and the curled edge 482 of the flow guide 454 to turn the direction of flow back towards the outlet passage 446.

The piston 486, the spring 528 and the frusto-conical portion 458 of the flow guide 454 are coordinated to measure flow through flow meter 414. The tubular portion 456 may also be part of this coordination. Since the enlarged head 490 of the piston 486 has a constant diameter, the radial distance between a perimeter of the enlarged head 486 and the frusto-conical portion 458 of the flow guide 454 increases as the piston 486 rises. This enables the flow meter 414 to have a reduced overall length (or height) when compared to a constant diameter flow guide. More specifically, in general, higher velocities mean a higher force on the enlarged head 490 of the piston 486. For an expanding area, such as that provided by the frusto-conical portion 458 of the flow guide 454, the velocity will decrease over the length for a given flow rate. So, at higher flow rates, the enlarged head 490 will be located in a section of the frusto-conical portion 458 with a larger cross-sectional area and, therefore, have a lower velocity. The advantage is that the flow meter can be shorter for the same flow rate range, and there will be a lower pressure drop. When there is no pressurized flow in the system, the enlarged head 490 of the piston 486 rests on the tapered ribs 472 of the flow guide 454. The flow sensor 410 can measure small amounts of flow downstream of a valve, which may indicate a leak in the valve. The flow sensor 410 also can measure above normal flows, which may indicate damaged connections, conduit or water emission devices downstream. It also could measure below normal flow amounts which may indicate clogged conduit or water emission devices.

The foregoing is illustrated by the following examples. In a first example, the flow sensor has an inlet of 1 in. and a flow guide with an inlet diameter of 1.25 in., an outlet diameter of 1.75 in., and an axial length of 2.396 in., as measured from the top of the ledges of the tubular portion to the upper edge of the frusto-conical portion. The straight/tubular portion of the flow guide has an axial length of 0.718 in., and the frusto-conical portion of the flow guide has an axial length of 1.678 in. and proceeds outward at an angle of 8.62°. The enlarged head of the piston has a diameter of 1.21 in., and there is a gap of 0.04 in. between the enlarged head and the tapered ribs, which run along the wall of the flow guide. The tapered ribs are designed to create a linear path for the piston to travel. Furthermore, the gap between the wall of the flow guide and the enlarged head increases as the piston travels away from the straight portion of the flow guide and through the frusto-conical portion of the flow guide.

The twisted shaft is 2.5 in. in length, and the pitch is 1.84 revolutions per inch (“rev/in”). The spring rate is 0.66 lb/in. In a preferred embodiment, with the foregoing dimensions and conditions, the angle in degrees for the markings on the dial indicate a given flow rate are shown in the table below.

Flow Rate (gpm) Angle (degrees) 0.0 0 0.5 23 5.0 160 10.0 215 15.0 260 20.0 304 25.0 342

In operation, the following table shows the enlarged head position from start of the ledges of the straight portion of the flow guide and the spring displacement for 5.0 gpm and 25.0 gpm flow rates.

Flow Rate Enlarged Head Position Spring Displacement (gpm) From Start (in.) (in.) 5.0 .7522 .7522 25.0 1.760 1.760

In a second example, the flow sensor has an inlet of 1.5 in., and the flow guide has an inlet diameter of 1.75 in., an outlet diameter of 2.3 in., and an axial length of 2.937 in., as measured from the top of the ledges of the tubular portion to the upper edge of the frusto-conical portion. The straight portion of the flow guide has an axial length of 0.960 in., and the frusto-conical portion has an axial height of 1.977 in. and proceeds outward at an angle of 8.14°. The enlarged head of the piston has a diameter of 1.600 in., and there is a gap of 0.05 in. between the enlarged head and the tapered ribs. The tapered ribs are designed to create a linear path for the piston to travel. Furthermore, the gap between the wall of the flow guide and the enlarged head increases as the piston travels away from the straight portion of the flow guide through the frusto-conical portion of the flow guide.

The twisted shaft is 3.15 in. in length, and the pitch of the twisted shaft is 2.60 rev/in. The spring rate is 2.5 lb/in. In a preferred embodiment, with the foregoing dimensions and conditions, the angle in degrees for the markings on the dial indicating a given flow rate are shown in the table below.

Flow Rate (gpm) Angle (degrees) 0.0 0 15 140 30 215 45 266 60 315 70 350

In operation, the following table shows the enlarged head position from the ledges of the straight portion and the spring displacement for 15.0 gpm and 70.0 gpm flow rates.

Flow Rate Enlarged Head Position Spring Displacement (gpm) From Start (in.) (in.) 15.0 1.01 1.01 70.0 2.52 2.52

As discussed in a previous example, a straight housing flow guide with a 1.25 in. inlet diameter and a spring rate of 0.80 lbs/in. had spring displacements of 0.19 in. and 4.78 in. for flow rates of 5.0 gpm and 25.0 gpm, respectively. The straight housing flow guide has a significantly larger displacement than the frusto-conical flow guide examples, as described above.

The foregoing dimensions and conditions are exemplary only. The dimensions and conditions and be changed to accommodate measuring larger or smaller flows.

As with previous embodiments, the helical springs and shafts of the flow sensors can be made of metal, such as stainless steel. The other components of the flow sensors can be made of plastic, such as acrylonitrile butadiene styrene (ABS), polymethyl methacrylate (PMMA), polypropylene (PP), and polyamides (PA).

With reference to FIG. 39, there is shown another flow sensor 710. The flow sensor 710 can be embedded into a fluid system, such as an irrigation system. The flow sensor 710 includes an inlet 712, an outlet 716, a pressure regulator 713, a body 715 and a flow meter 714. Some elements may be the same as those presented in previous embodiments and will retain the same reference numbers for clarity. This embodiment includes a combined filter and flow guide. Therefore, it may also be used, along with a dial and a plunger cap assembly, to easily retrofit existing filter assemblies to be both a filter and flow sensors. In these retrofitted instances the body of the filter assembly is left installed in the irrigation system and reused.

The inlet 712 and the outlet 716 are configured for attachment of the flow sensor 710 to conduits in an irrigation system. The inlet 712 has exterior threading 720 for being threaded into an interior threaded conduit end. The outlet 716 also has exterior threading 727 for cooperating with interior threading on a downstream conduit end. Instead of threading, other attachment methods may be used, such as gluing, clamping or welding.

With reference to FIGS. 39 and 40, the flow meter 714 includes an upper portion 732 and a base portion 740. The upper portion 732 and the base portion 740 form the body 715. The body 715 may be a single continuous piece, with the inlet 712 and the outlet 716 at opposite sides of the base portion 740. The single piece body 715 requires fewer mechanical parts and is both easier to repair and to manufacture and assemble into the flow sensor 710. A top cover 728 has internal threading 729 for threading onto external threading 731 of the upper portion 732.

The base portion 740 defines an inlet passage 744 and an outlet passage 746. The inlet passage 744 is defined in part by an upward directed tubular portion 748 at the center of the base 740. The outlet passage 746 extends around the tubular portion 748 and over a portion of the inlet passage 744 upstream of the tubular portion 748.

The upper portion 732 may be cylindrical in shape and has a vertical configuration relative to the base 740. The body 715 forms a lower chamber 750, and the top cover 728 defines an upper chamber 752. The lower chamber 750 houses a filter 753 and a flow guide 754. The filter 753 and the flow guide 754 form a single piece flow guide/filter body 755 (e.g., FIG. 42).

As shown in FIG. 43, the flow guide 754 includes a tubular lower portion 756 with walls 745 that taper slightly inwards from a base 779 of the flow guide 754 to a middle portion 781 of the flow guide 754. The flow guide 754 also includes a tubular upper portion 758 with an annular inner wall 757 that taper inwards from an upper edge 782 down to a transition 781 to the tubular lower portion 756 of the flow guide 754. The rate of taper of the tubular lower portion 756 is smaller than the rate of taper of the tubular upper portion 758. More specifically, the rate of taper of tubular lower portion 756 can be relatively negligible for the function of the flow meter 714 and can be determined merely to accommodate the molding process. The rate of taper for the tubular upper portion 758 can be set at any desired angle; however, it is generally bounded by the radial and vertical space available in the portion of the chamber 750 inside of the filter 753 and the diameter of the enlarged head 490. The function of the tubular upper portion 758 can be mainly controlled by the spring constant of the spring 518 as opposed to the rate of taper.

The tubular lower portion 756 has a slightly larger inner diameter than the outer diameter of the upwardly directed tubular portion 748 of the inlet passage 744 so that the tubular portion 756 can slide on to the outside of the tubular portion 748 with a friction fit that forms a seal. The transition 781 includes a chamfered surface 806 and a stepped surface 776 that engage complimentary surfaces on the terminal end 766 of the tubular portion 748 of the inlet passage 744.

With reference to FIGS. 42 and 43, the flow guide/filter body 755 may be molded as a single piece or it may be assembled with multiple components. For example, the flow guide may be a separate component affixed to the filter body. The flow guide/filter body 755 includes an annular base 787 of the filter 753. The annular base 787 defines slots 788 configured to receive tooling to hold the mesh screen 794 during the molding process. A portion of the annular base 787 seats on a ledge 745 (FIG. 41) of the inlet passage 744 and terminal ends of ribs 805 (see FIG. 44) that extend radially inward from the upper portion 732 near the base portion 740 (see FIG. 44). The filter 753 has supports 789 extending longitudinally from the annular base 787 to an annular top 791 of the filter 753. The supports 789 may be equally spaced from one another about the diameter of the annular base 787. The supports 789 may take on a rectangular cross-sectional shape or some other shape, such as a cylindrical, triangular or a trapezoidal cross-section. The top 791 also has a lower ring 795. An upper ring 797 is on top of the lower ring 795. The upper ring 797 has a larger outer diameter than the lower ring 795. The upper ring 797 defines notches 793 equally spaced about the diameter of the upper ring 797.

A mesh screen 794 could be fixed inside the filter body 753 to the lower ring 795, the annular base 787 and the filter support elements 789. For example, the mesh screen 794 could be over-molded onto the lower ring 795, the annular base 787 and the filter support elements 789. The mesh screen 794 filters debris from the water flowing through the filter. Alternatively, the mesh screen 794 could be a cylinder that slides into the filter body 753. Also, the mesh screen 794 could be mounted to the outside of the filter body 753.

The upper ring 797 includes a flange 801 so that the flow guide/filter body 755 seats on an annular recess ledge 799 (FIG. 41) of the upper portion 732 of the flow body 715. With reference to FIG. 42, tabs 803 extend radially from the annular base 787 and fit in-between the ribs 805 to prevent rotation of the flow guide/filter body 755.

The annular inner wall 757 of the tubular upper portion 758 of the flow guide 754 allows water to flow outward as it moves to the top of the upper chamber 752. Water will flow past the upper edge 782 into the lower chamber 750 and down toward the outlet passage 746. For further assistance in redirecting the flow, the upper chamber 752 includes an arcuate, annular portion 784 (FIG. 39).

In a manner similar to previous embodiments, and with reference to FIGS. 39 and 40, the piston 486 operates in the both the lower and upper chambers 750, 752 of the upper portion 732. The piston 486 includes the shaft 488 with the hollow interior 500, the shaft head 506, and the plunger 499 of the top cover 728. The plunger 499 includes the enlarged head 490 with the tubular portion 498 fixed thereto. The enlarged head 490 operates in the flow guide 754 and fits into the tubular portion 748 of the inlet passage 744 with a slight clearance so that fluid can flow around the enlarged head 490 to be more sensitive to low flow rates so that they can be measured when the enlarged head 490 is in the tubular portion 498 overlapped with the tubular portion 756. The clearance between the enlarged head 490 and the inside diameter of the tubular portion 748 is preferably approximately 0.020 inches. As shown in FIGS. 26 and 27, the annular bead 492 of the tubular portion 498 engages the fingers 494 of the shaft 488. More specifically, the fingers 494 each have grooves 496 that receive the annular bead 492 of the tubular portion 498 allowing the shaft 488 to securely connect to the tubular portion 498 of the plunger 499. Alternatively, the fingers could extend from the tubular portion and the annular bead could be about shaft.

With reference to FIGS. 45 and 46, a tubular portion 810 of the top cover 728 forming the upper chamber 752 attaches to a washer 816. The washer 816 is disposed below the shaft head 506 about the shaft 488. When there is no flow, the shaft head seats on the washer 816. The washer 816 has a series of recesses 827 to reduce the amount of material used in manufacturing. As shown in FIGS. 45-48, the tubular portion 810 of the top cover 728 has flexible fingers 814. Each flexible finger 814 can bend radially inward and outward. Each flexible fingers 814 has a lip 815 that clips to the underside of a ledge 823 formed by an annular recess 825 of the washer 816 and snaps the tubular portion 810 securely to the washer 816.

The enlarged head 490 is centered in the flow guide 454 by a wall 745 of the tubular portion 748 of the inlet passage 744. When water is flowing through the flow guide 754, the wall 745 of the tubular portion 748 permits the piston 486 to move up and down linearly with minimal friction between the enlarged head 490 and the wall 745.

As the piston 486 moves upward, the shaft 488 extends into the tubular portion 810 of the top cover 728, as shown in FIGS. 39 and 46. More specifically, the present embodiment may have the same shaft head 506 with the rectangular hole 513 at the center of the shaft head 506 as shown in FIGS. 26 and 27. The rectangular hole 513 make take on some other shape, such as a square or a triangle. The rectangular hole 513 is of a slightly larger size than the cross-sectional dimensions of the twisted shaft 528. The cross-sectional shape can have the same shape as the hole 513. That is, with a square shaped hole, the twisted shaft could have a square shaped cross-sectional shape. The same correspondence could be done for the other shapes. As the rate of water flow increases in the flow meter 714, the piston 486 will move up the twisted shaft 528, and the twisted shaft 528 will move into the hollow interior 500 of the shaft 488. As a result of this interaction, the twisted shaft 528 will convert the linear motion of the shaft 488 into rotational motion of the twisted shaft 528.

The tubular portion 810 houses the helical spring 518 and the twisted shaft 528 in the chamber 752. The tubular portion 810 also has ribs 830 (FIG. 47) that run longitudinally therein. The ribs 830 provide a smaller surface that, in turn, reduces friction so that the helical spring 518, the shaft 488 and the shaft head 506 move freely up and down linearly, but are maintained in a linear operating configuration. This ensures that the plunger 499 remains centrally located in the flow guide 754 and the tubular portion 748 of the inlet passage 744. As water flows up the inlet passage 744 and pushes on the piston 486, the piston 486 is biased downward from the helical spring 518. The upward displacement of the piston 486 depends on the rate of flow of the water into the inlet passage 744. A higher flow rate will push the shaft 488 higher into the tubular portion 810 of the top cover 728 than a lower flow rate. If there is no water flow, the shaft 488 will not extend into the tubular portion 810. The tubular upper portion 758 may include longitudinally extending ribs 761 that are wedged shaped and that engage and guide the enlarged head 490 as it reciprocates. It also provides clearance for the water to pass around the enlarged head 490 and low friction surfaces for the enlarged head 490 to move on as it reciprocates.

The rate of flow through the inlet passage may be sufficient enough to upwardly force the enlarged head 490 of the piston 486 to move in the flow guide tubular upper portion 758. Despite the inner diameter of the tubular upper portion 758 being larger than the diameter of the enlarged head 490 at any point within the tubular upper portion 758, the piston will still be guided to move vertically (and not laterally) since the shaft head 506 is centered in the tubular portion 810 by the ribs 830 of the tubular portion 810.

The top of the tubular portion 810 has an annular wall 811 extending longitudinally into the chamber 752. The piston 486 cannot rise vertically beyond the annular wall 811. The outer diameter of the annular wall 811 is smaller than the inner diameter of the helical spring 518, and the inner diameter of the tubular portion 810 is larger than the outer diameter of the helical spring 518. Therefore, as the piston 486 drives upward into the chamber 752, the helical spring 518 can coil up and collect around the annular wall 811 and inside the tubular portion 810.

To prevent the piston 486 from rotating within the tubular portion 810 of the top cover 728, the rib 508 (FIGS. 26 and 27) of the shaft head 506 slides vertically within a longitudinally running groove 812 (FIG. 48) of the tubular portion 810.

With reference to FIGS. 46, 48, and 49, the tubular portion 810 terminates at a top portion 836 of the top cover 728. The top portion 836 defines a hole 832 that permits the spindle 542 to connect the twisted shaft 528 to a dial pointer 852 of a dial assembly 844. As described in a previous embodiment (see FIGS. 33-34), and with reference to FIGS. 46 and 49, the spindle 542 has ridges 543 running longitudinally along the upper portion 547 and the lower portion 549. The end of the lower portion 549 fits in the hole 832 of the boss 529 of the twisted shaft 528 with a friction fit, and the ridges 543 penetrate the surface of the boss 529 forming the hole 832 to prevent rotation of the spindle 542 within the hole 832. The boss 529 also has a series of recesses 531 to reduce the amount of material used in manufacturing. The upper portion 547 of the spindle 542 has a conical tip 551 that is accommodated by the tubular tip 554. The connection is a friction fit. The ridges 543 penetrate into the inner surface of the tubular tip 554 to secure the dial pointer 852 to the spindle 542 and prevent rotation of the spindle 542 within the tubular tip 554 of the dial pointer 852. Therefore, as the spindle 542 rotates due to the rotation of the twisted shaft 528, the dial pointer 852 rotates at the same rate as the spindle 542.

In a similar manner as described in a previous embodiment, the retention clip 553 seats in-between the dome-shaped portion 503 (see e.g., FIG. 29) of the top cover 728. The retention clip 553 is fastened around the groove 545 of the intermediate portion 559 of the spindle 542 to prevent axial movement of the spindle 542. The retention clip 553 has a C-shaped split ring configuration. The spindle has washers 851 (FIG. 40) that seat above and below the retention clip 553. The dome-shaped portion 503 houses the annular seal 555 (FIG. 34). The seal 555 has redundant wipers 557 that wrap around and engage the spindle 542 to prevent water from exiting the enclosure 502 through the hole 832 of the top cover 728.

Referring to FIG. 49, the dial assembly 844 also includes a dial 846 and a transparent dial cover 850. The twisted shaft 528, the spindle 542 and the dial pointer 852 are splined together such that they rotate together. The twist in the twisted shaft 528 turns the twisted shaft 528, the spindle 542 and the dial pointer 852 as the shaft 487 extends higher into the tubular portion 810 of the top cover 728 as water flow increases through the flow meter 714.

The dial 846 has tabs 858 that seat in complimenting grooves 870 of a dial seat 859 to prevent the dial 846 from rotating. The dial 846 may be marked with indicia or indicators 883 for the amount of water flow through the flow meter 714. For instance, the dial 846 may have indicia 883 indicating a scale for water flow in gallons per minute and/or liters per minute. As the flow rate increases, the dial pointer 852 will rotate in a clockwise fashion as viewed from above the flow sensor 710.

With reference to FIGS. 51 and 52, the dial seat 859 has a recess 860 that receives a protrusion 855 of the top cover 728 which prevents the dial seat from rotating as the spindle 542 rotates inside a hole 862 of the dial seat 859. The dial seat 859 seats on top of the top cover 728 and is further secured to the top cover 728 with set screws 871 (FIG. 49). The set screw 871 has a non-traditional tool socket (e.g., a hex tool socket) to aid in prevention of vandalism or unintentional removal. Each set screw 871 pass through holes 861 of the dial seat 859 and may be threaded into holes 853 of bosses 887 of the top cover 728. The top cover 728 has series of recesses 857 to reduce the amount of material used in manufacturing.

With reference to FIGS. 50 and 53, a flow rate gauge 880 connects to the dial assembly 844 and the top cover 728. The flow rate gauge 880 has a semi-annular recess 882 that accommodates the dial seat 859 and allows the flow rate gauge 880 to slide around the perimeter of the dial assembly 844. As the flow rate increases, the dial pointer 852 will rotate in a clockwise fashion as viewed from above the flow sensor 710. The flow rate gauge 880 indicates whether the flow rate through the flow sensor 710 is within the normal gpm range or has either increased or decreased by some amount beyond the normal gpm range. For example, if a normal flow through a particular system is 10 gpm, a user will move the flow rate gauge 880 to indicate this flow rate of 10 gpm.

The flow rate gauge 880 can have color coded sections that designate flow rate ranges. For example, an inner section 884 may be green indicating normal flow, and outer sections 885 that straddle the inner section 884 may have other colors (e.g., yellow and red) indicating undesirable flow ranges. The transparent dial cover 850 permits the user to still be able to visually observe the dial pointer 852 and the markings 883 on the dial 846.

The dial 846 also starts with smaller intervals, such as 0, 1, 2, 5 gpm and transitions to longer intervals, such as 10 and 20 gpm. The ability to have this setup is provided by the flow guide 754 first having a lower cylindrical portion and then an upper frusto-conical portion.

With reference to FIG. 54 and FIG. 56, there is shown an alternative top cover 928, flow gauge 980 and dial assembly 944. The top cover 928 has a tubular portion 910, an annular ledge 961 and an annular top ring 963. The tubular portion 910 has ribs 930 (FIG. 57) that run longitudinally therein. The ribs 930 provide a smaller surface that, in turn, reduces friction so that the helical spring 518, the shaft 488 and the shaft head 506 move freely up and down linearly, but are maintained in a linear operating configuration. To prevent the piston 486 from rotating within the tubular portion 910 of the top cover 928, the rib 508 (FIGS. 26 and 27) of the shaft head 506 slides vertically within a longitudinally running groove 912 (FIG. 57) of the tubular portion 910.

The dial assembly 944 includes a dial 946 and a transparent dial cover 950. As with previous embodiments, the twisted shaft 528, the spindle 542 and the dial pointer 852 are splined together such that they rotate together. The twist in the twisted shaft 528 turns the twisted shaft 528, the spindle 542 and the dial pointer 852 as the shaft 487 reciprocates in the tubular portion 810 of the top cover 928 as water flow increases and decreases through the flow meter 714.

The transparent dial cover 950 snap fits on to a top cover body 934. More specifically, an o-ring 995 seats in an annular recess 959 of the body 934, and the transparent dial cover 950 includes an inner annular recess 931 complimentary in shape to the o-ring 995. The transparent dial cover 950 can slide over the o-ring 995 and snap fit securely to the top cover body 934.

The dial 946 has radial tabs 958 that seat in complementary radial grooves 960 of the top ring 963 of the top cover 928 to prevent the dial 946 from rotating. The dial 946 may be marked with indicia or indicators 933 for the amount of water flow through the flow meter 714. For instance, the dial 946 may have indicia 933 indicating a scale for water flow in gallons per minute (gpm) and/or liters per minute. As the flow rate increases, the dial pointer 852 will rotate in a clockwise direction as viewed from above the flow sensor 710, and as the flow rate decreases, the dial pointer 852 will rotate in a counter-clockwise direction as viewed from above the flow sensor 710.

With reference to FIGS. 55, 56, and 57, when the top cover 928 and the dial assembly 944 are in an assembled configuration, the flow rate gauge 980 clamps to the dial assembly 944 and the top cover 928. The transparent dial cover 950 has an annular flange 951 about its perimeter that engages the annular ledge 961 of the top cover 928. The flow rate gauge 980 has an indicator portion 981 and a base portion 982, wherein the flange 951 of the dial cover 950 and the ledge recess 961 of the top cover 928 are sandwiched between the indicator portion 981 and the base portion 982. Specifically, the ledge recess 951 seats on a lower seat 923 of the base portion 982 of the flow rate gauge 980. A bottom surface 924 of the indicator portion 981 seats on an outer seat 920 of the base portion 982. The flange 951 sits on the inner seat 927, the outer seat 920 and the rail 921. The flange 952 includes an annular groove 932 that receives the complimentary shaped rail 921 of the base portion 982 to guide the flow rate gauge 980 about the perimeter of the dial assembly and further assists preventing the flow rate gauge 980 from unintentionally releasing from the dial assembly 944.

The indicator portion 981 and the base portion 982 clamp the dial cover 950 and the top cover 928 with a screw 983. The screw 983 has a non-traditional tool socket (e.g., a hex tool socket). The screw 983 passes through a hole 991 of a first boss 992 of the indicator portion 981 and then a hole 926 of a second boss 993 of the base portion 982. A spring washer 987 sits in a spring washer recess 925 about the hole 926. The hole 926 can be pre-threaded or self-threaded on the initial instillation of the screw 983. The indicator portion 981 defines a partially cylindrical recess 997 to accommodate the head of the screw 883. The spring washer 987 maintains tension on the screw 983 so that the indicator portion 981 and the base portion 982 do not unintentionally loosen from one another.

The screw 983 may be loosened to manually slide the flow rate gauge 880 around the perimeter of the dial assembly 944. The indicator portion 981 extends upward so not to contact the dial cover 950 as the flow rate gauge 980 is moved about the perimeter of the dial cover 950. As the flow rate changes, the dial pointer 852 will rotate. The flow rate gauge 980 indicates whether the flow rate through the flow sensor 710 is within the normal gpm range defined on the indicator portion 981 or has either increased or decreased by some amount beyond the normal gpm range.

More specifically, if a normal flow through a system is 10 gpm, a user will move the flow rate gauge 980 to indicate this flow rate of 10 gpm as the normal operating flow for the system. The flow rate gauge 980 can have color coded sections that designate flow rate ranges. For example, an inner section 984 may be green indicating normal flow, and outer sections 985 that straddle the inner section 884 may have other colors (e.g., yellow and red) indicating undesirable flow ranges. The transparent dial cover 950 permits the user to visually observe the dial pointer 852 and markings 983 on the dial 946.

In some cases, if the flow rate is observed to decrease from irrigation cycle to irrigation cycle, this may indicate that the filter 783 may be getting clogged with debris. For example, if the normal flow rate through the flow sensor 710 is 20 gpm and the flow rate has dropped to 16 gpm over a period time (e.g., a few days) this may be an indication that debris in the filter 783 is inhibiting water to pass through the filter 783 and flow downstream.

In operation, fluid flows into the flow sensor 710 through the inlet passage 744. As the flow increases, the fluid moves the piston 486 upwards in the lower and upper chambers 750, 752. The piston 486 causes the dial assembly 844 to determine the flow rate through the flow sensor 710. That is, the upward movement of the piston 486 against the helical spring 518 causes the twisted shaft 528 to turn and twist in the chamber 752. The twisting of the twisted shaft 528 converts linear motion of the piston 486 to rotational motion, and rotates the dial pointer 852 about the dial 846 indicating the flow through the flow meter 714 of the flow sensor 710. As the flow meter 714 is measuring the flow, the fluid flows around the enlarged head 490 of the piston 486 and through the flow guide 754. Then, the flow is guided by the accurate, annular portion 784 of the upper portion 732 of the flow guide 754 to turn the direction of flow back towards the outlet passage 746. The flow passes through the mesh screen 794 of the filter 753 to flow to the outlet passage 746.

The piston 486, the spring 518, the twisted shaft 528 and the flow guide 754 are coordinated to measure flow through flow meter 714. Since the enlarged head 490 of the piston 486 has a constant diameter, the radial distance between a perimeter of the enlarged head 486 and the upper tubular portion 758 of the flow guide 754 increases as the piston 486 rises. This enables the flow meter 714 to have a reduced overall length (or height) when compared to a constant diameter flow guide. More specifically, in general, higher velocities mean a higher force on the enlarged head 490 of the piston 486. For an expanding area, such as that provided by the conical tapered wall 758 of the upper tubular portion 758 of the flow guide 754, the velocity will decrease over the length for a given flow rate. So, at higher flow rates, the enlarged head 490 will be located in a section of the upper tubular portion 758 with a larger cross-sectional area and, therefore, have a lower velocity. The advantage is that the flow meter can be shorter for the same flow rate range, and there will be a lower pressure drop.

Additionally, the combined flow guide/filter body 755 formed by the integration of the flow guide 754 into the filter 753 allows for the simple manufacturing of a flow guide system coupled with a filter to prevent clogging and damage to the irrigation system. It also provides the ability to retrofit existing filter bodies to become both a filter and a flow sensor. One can simply do this by removing the filter top and the filter. Then, the combined filter and flow guide is inserted into the body. The filter cap is replaced with a new cap assembly that includes the dial assembly 844 (or with the dial assembly 944 and top cover 928), the piston 486, the top cover 728, the twisted shaft 528, the washer 816 and the helical spring 518 all assembled as a single unit,

The flow sensor 710 can measure small amounts of flow downstream of a valve, which may indicate a leak in the valve. The flow sensor 710 also can measure above normal flows, which may indicate damaged connections, conduit or water emission devices downstream. It also could measure below normal flow amounts which may indicate clogged conduit or water emission devices.

As with previous embodiments, the helical springs and shafts of the flow sensors can be made of metal, such as stainless steel. The other components of the flow sensors can be made of plastic, such as acrylonitrile butadiene styrene (ABS), polymethyl methacrylate (PMMA), polypropylene (PP), and polyamides (PA).

Dimensions and flow rates may be similar to previous embodiments and are only exemplary. The dimensions and conditions can be changed to accommodate measuring larger or smaller flows. For example, to target a smaller maximum flow rate (e.g., set the maximum flow rate to 10 gpm from 20 gpm), the flow sensor can be fitted with a lighter spring (i.e., a lower spring constant). This device will perform in a similar fashion as the previous designs. This version has been scaled down to accommodate a smaller package so to be able to also be able to fit into existing filter bodies. The target is 0 to 20 gpm instead of 0 to 25 gpm. The lower range is due to the smaller size of the body, and in some instances, there is a recommended flow rate for filters of 20 gpm. It should also be further understood that the flow range of the unit can be tuned to any desired range by changing the spring rate. If a smaller range (0 to 10 gpm) is desired, then a lighter spring (lower spring constant spring) is used to obtain the same travel, both linearly/rotationally, of the pointer or arrow. This version can also be scaled as desired to accommodate higher and lower flow rates.

The matter set forth in the foregoing description and accompanying drawings is offered by way of illustration only and not as a limitation. While particular embodiments have been shown and described, it will be apparent to those skilled in the art that changes and modifications may be made without departing from the broader aspects of the technological contribution. The actual scope of the protection sought is intended to be defined in the following claims. 

What is claimed is:
 1. A flow sensor comprising: a body; a combined flow guide and filter unit associated with the body; a piston operating in the combined flow guide and filter unit based on an amount of fluid flowing through the flow sensor; a flow indicator assembly to indicate the flow through the flow sensor based on movement of the piston in the combined flow guide and filter unit.
 2. The flow sensor of claim 1 wherein the combined flow guide and filter is attached to an inlet passage portion of the body.
 3. The flow sensor of claim 2 wherein the plunger operated in the inlet passage portion and the combined flow guide and filter unit based on an amount of fluid flowing throwing the flow sensor.
 4. The flow sensor of claim 3 further comprising a shaft converting linear motion of the piston to rotational movement of the shaft.
 5. The flow sensor of claim 1 wherein the combined flow guide and filter unit is a single piece flow guide and filter.
 6. The flow sensor of claim 1 wherein the combined flow guide and filter has a mesh screen to filter debris from fluid.
 7. The flow sensor of claim 1 wherein the flow guide includes at least a frusto-conical portion.
 8. The flow sensor of claim 1 further comprising a top cover that threads onto the body, the top cover carries the flow indicator assembly.
 9. The flow sensor of claim 4 further comprising a first chamber housing the shaft.
 10. The flow sensor of claim 9 further comprising a spring biasing the piston upstream in the combined flow guide and filter unit.
 11. The flow sensor of claim 4 wherein the flow indicator assembly further comprises an indicator that points to indicia indicating the current amount of flow through the flow sensor based on rotational movement of the shaft.
 12. The flow sensor of claim 11 wherein the flow indicator assembly includes a flow gauge to indicate a proper flow condition.
 13. The flow sensor of claim 7 further wherein the at least a frusto-conical portion includes a first frusto-conical portion and a second frusto-conical portion upstream of the first frusto-conical portion of the flow guide, the first frusto-conical portion having a greater taper than the second frusto-conical portion.
 14. The flow sensor of claim 13 wherein the wherein the first frusto-conical portion and the second frusto-conical portion are contiguous.
 15. The flow sensor of claim 13 wherein the second frusto-conical portion is a straight, cylindrical portion.
 16. The flow sensor of claim 1 wherein the combined flow guide and filter has an annular base and an annular top.
 17. The flow sensor of claim 16 wherein the combined flow guide and filter has supports extending longitudinally from the annular base to the annular top.
 18. The flow sensor of claim 17 wherein a mesh screen is associated with the supports.
 19. A method of converting a filter assembly to a flow sensor and filter assembly comprising the steps of: removing a cover of a filter assembly; removing a filter basket from a body of the filter assembly; installing a combined flow guide and filter assembly in the body of the filter assembly; and installing a cap assembly in place of the cover, the cap assembly including a plunger operating in the combined flow guide and filter assembly and a flow indicator assembly that converts linear movement of the plunger to a flow measurement.
 20. The method of claim 19 wherein the flow indicator includes converting linear movement of the plunger to rotational movement of a flow indicator corresponding to a flow measurement.
 21. The method of claim 20 wherein the flow indicator assembly includes a dial with indicia indicating amounts of flow being measured.
 22. The method of claim 21 wherein the flow indicator assembly is preassembled.
 23. The method of claim 22 wherein the cap assembly has a thread connection to the body. 